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Evolution of the Human Diet and Its Impact on Gut Microbiota, Immune Responses, and Brain Health.
González Olmo, BM, Butler, MJ, Barrientos, RM
Nutrients. 2021;13(1)
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One explanation for the increased prevalence in chronic disease and mental illness is from the evolutionary perspective. This suggests the rapid shift in diet towards processed foods in the past 200 years has not allowed for sufficient adaptation of the gut microbiome. The gut microbiome plays an important role in the digestive, immune and nervous systems via the gut-brain axis, and may be a key factor in modulating inflammation and disease. The aim of this review is to discuss how what we eat affects the immune system and impacts our brain health. The literature currently shows significant associations between the Western diet and its impact on the health of the gut microbiome and the brain. Increased intake of saturated fats, refined carbohydrates and sugar, coupled with a reduction in fiber, negatively impacts the digestive system and elicits an immune response. This response can lead to neuroinflammation, which is now found to be associated with deficits in learning and memory, as well as increased rates of neurodegenerative disease and depression. Based on the existing literature, the authors conclude the human gut microbiome has not had sufficient time to adapt to many modern foods, thus leading to inflammation and disease. The authors recommend that a diet composed of natural whole foods with minimal processing can help prevent and alleviate some of the burden caused by chronic disease, and suggest future studies focus on improving techniques to evaluate neuroinflammation in humans.
Abstract
The relatively rapid shift from consuming preagricultural wild foods for thousands of years, to consuming postindustrial semi-processed and ultra-processed foods endemic of the Western world less than 200 years ago did not allow for evolutionary adaptation of the commensal microbial species that inhabit the human gastrointestinal (GI) tract, and this has significantly impacted gut health. The human gut microbiota, the diverse and dynamic population of microbes, has been demonstrated to have extensive and important interactions with the digestive, immune, and nervous systems. Western diet-induced dysbiosis of the gut microbiota has been shown to negatively impact human digestive physiology, to have pathogenic effects on the immune system, and, in turn, cause exaggerated neuroinflammation. Given the tremendous amount of evidence linking neuroinflammation with neural dysfunction, it is no surprise that the Western diet has been implicated in the development of many diseases and disorders of the brain, including memory impairments, neurodegenerative disorders, and depression. In this review, we discuss each of these concepts to understand how what we eat can lead to cognitive and psychiatric diseases.
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Probiotics, Prebiotics and Postbiotics on Mitigation of Depression Symptoms: Modulation of the Brain-Gut-Microbiome Axis.
Chudzik, A, Orzyłowska, A, Rola, R, Stanisz, GJ
Biomolecules. 2021;11(7)
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The bidirectional communication pathway between the gut microbiota and the central nervous system has been termed the brain-gut-microbiome axis. Increased investigation of this pathway has found the gut bacteria to impact metabolism and the brain, suggesting that modulating the microbiome may elicit change in mental health. The aim of this review is to discuss the current findings in both animal and human studies regarding the use of pro-, pre- and post-biotics in the prevention and treatment of depressive disorders. Studies show that modulating the bacteria in the gut may reduce inflammation, decrease stress hormone levels and adjust the levels of neurotransmitters in the brain. These changes consequently lead to the reduction of depressive symptoms and improvement in mood. While these results are promising, larger clinical trials are needed that include biochemical measurements and fecal microbiome analysis in addition to validated questionnaires. With this in mind, the authors conclude there is huge potential in the role of nutrition as a therapeutic target for neurological and mental health conditions.
Abstract
The brain-gut-microbiome axis is a bidirectional communication pathway between the gut microbiota and the central nervous system. The growing interest in the gut microbiota and mechanisms of its interaction with the brain has contributed to the considerable attention given to the potential use of probiotics, prebiotics and postbiotics in the prevention and treatment of depressive disorders. This review discusses the up-to-date findings in preclinical and clinical trials regarding the use of pro-, pre- and postbiotics in depressive disorders. Studies in rodent models of depression show that some of them inhibit inflammation, decrease corticosterone level and change the level of neurometabolites, which consequently lead to mitigation of the symptoms of depression. Moreover, certain clinical studies have indicated improvement in mood as well as changes in biochemical parameters in patients suffering from depressive disorders.
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The Role of the Gut Microbiota in Dietary Interventions for Depression and Anxiety.
Bear, TLK, Dalziel, JE, Coad, J, Roy, NC, Butts, CA, Gopal, PK
Advances in nutrition (Bethesda, Md.). 2020;11(4):890-907
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A growing body of research suggests diet and mental health are closely connected through the microbiome-gut-brain axis (MGBA). This axis shows how the gut and brain are linked in a bidirectional relationship, and provides a model in which dietary interventions could help prevent, or be an alternative therapy, for depression and anxiety. While there is an increased understanding of the complex interplay between diet, gut microbiome and mental health, the literature has produced conflicting results. The aim of this review is to discuss possible reasons for the conflicting results on the link between diet and mental health and present the current findings. The authors explored the impact of various dietary components on the MGBA including macronutrient ratios, omega 3 fatty acids, prebiotic and probiotic foods, food additives, and whole diet approaches. The research shows mental health is likely to be influenced by the MGBA via changes in gut microbiota composition and function, but conflicting results and limited research elucidates the complexity in understand the extent of this bidirectional relationship. Based on the current findings, the authors suggest dietary patterns for positive mental health should be in support of a healthy gut microbiota. They conclude further research is needed into the mechanisms in which gut microbiota impacts mental health to pave the way for a holistic approach to preventing and treating anxiety and depression.
Abstract
There is emerging evidence that an unhealthy dietary pattern may increase the risk of developing depression or anxiety, whereas a healthy dietary pattern may decrease it. This nascent research suggests that dietary interventions could help prevent, or be an alternative or adjunct therapy for, depression and anxiety. The relation, however, is complex, affected by many confounding variables, and is also likely to be bidirectional, with dietary choices being affected by stress and depression. This complexity is reflected in the data, with sometimes conflicting results among studies. As the research evolves, all characteristics of the relation need to be considered to ensure that we obtain a full understanding, which can potentially be translated into clinical practice. A parallel and fast-growing body of research shows that the gut microbiota is linked with the brain in a bidirectional relation, commonly termed the microbiome-gut-brain axis. Preclinical evidence suggests that this axis plays a key role in the regulation of brain function and behavior. In this review we discuss possible reasons for the conflicting results in diet-mood research, and present examples of areas of the diet-mood relation in which the gut microbiota is likely to be involved, potentially explaining some of the conflicting results from diet and depression studies. We argue that because diet is one of the most significant factors that affects human gut microbiota structure and function, nutritional intervention studies need to consider the gut microbiota as an essential piece of the puzzle.
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Gut microbes in neurocognitive and mental health disorders.
Halverson, T, Alagiakrishnan, K
Annals of medicine. 2020;52(8):423-443
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Adequately and effectively treating and managing neurocognitive disorders remains a challenge. Increasing evidence suggests gut microbes may contribute to common mental health disorders through the microbiota-gut-brain axis, and better understanding this interaction could lead to improved clinical outcomes. The aim of this review is to discuss the impact of the gut microbiome on neurocognitive and mental health disorders and the mechanisms by which they act. This review reveals that the gut microbiome can influence brain and intestinal cells and that there is an association between gut dysbiosis with different mental health and neurocognitive disorders. Additionally, evidence shows the antimicrobial effect of current pharmaceutical treatments used in mental disorders may adversely affect the gut microbiome. Based on these findings, the authors conclude the gut microbiome is likely involved in the pathophysiology of neurocognitive and mental health conditions. Treatment strategies focusing on the gut microbiome may have a role in the treatment and management of mental health disorders, however further evidence is needed before applying these strategies in clinical practice.
Abstract
INTRODUCTION As individuals age, the prevalence of neurocognitive and mental health disorders increases. Current biomedical treatments do not completely address the management of these conditions. Despite new pharmacological therapy the challenges of managing these diseases remain.There is increasing evidence that the Gut Microbiome (GM) and microbial dysbiosis contribute to some of the more prevalent mental health and neurocognitive disorders, such as depression, anxiety, obsessive-compulsive disorder (OCD), post-traumatic stress disorder (PTSD), schizophrenia, bipolar disorder (BP), and dementia as well as the behavioural and psychological symptoms of dementia (BPSD) through the microbiota-gut-brain axis. Methodology: Scoping review about the effect of gut microbiota on neurocognitive and mental health disorders. RESULTS This scoping review found there is an evolving evidence of the involvement of the gut microbiota in the pathophysiology of neurocognitive and mental health disorders. This manuscript also discusses how the psychotropics used to treat these conditions may have an antimicrobial effect on GM, and the potential for new strategies of management with probiotics and faecal transplantation. CONCLUSIONS This understanding can open up the need for a gut related approach in these disorders as well as unlock the door for the role of gut related microbiota management. KEY MESSAGES Challenges of managing mental health conditions remain in spite of new pharmacological therapy. Gut dysbiosis is seen in various mental health conditions. Various psychotropic medications can have an influence on the gut microbiota by their antimicrobial effect.
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Bridging the Reciprocal Gap between Sleep and Fruit and Vegetable Consumption: A Review of the Evidence, Potential Mechanisms, Implications, and Directions for Future Work.
Noorwali, E, Hardie, L, Cade, J
Nutrients. 2019;11(6)
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Both sleep disruption and a low intake of fruit and vegetables (FV) are associated with higher rates of premature death and chronic disease. This review looked at previous studies in order to determine whether there is a link between sleep and FV consumption. A recent meta-analysis found that shorter sleep duration is consistently associated with low fruit and vegetable intake in children, but in adults the association is less clear. Studies looking at the effect of sleep on FV intake had variable results. Tart cherries and kiwi fruits were the most commonly studied fruits for their effect on sleep measures. Observational studies tended to find that both short- and long-sleepers tend to eat less FV than those that sleep for 7-8 hours. A lot of evidence shows that people who go to sleep later (‘owls’) tend to consume unhealthier diets with lower intakes of FV than people who go to bed earlier (‘larks’). The researchers also looked at potential mechanisms for the association between sleep and FV intake. Polyphenols in FV may influence sleep by increasing neurotransmitters via the gut-brain axis, improving energy metabolism and through alterations in circadian rhythms and the CLOCK genes. Ways in which disrupted sleep may affect FV consumption included changes in hunger hormones, emotional stress and impaired decision making. With further research, interactions between sleep measures and FV consumption may be clarified and potentially reduce the burden of chronic diseases and premature deaths.
Abstract
A substantial burden of disease and mortality globally is attributable to both sleep disruption and low intakes of fruit and vegetable (FV) and there is increasing mechanistic and epidemiological evidence to support a reciprocal relationship between the two. This review provides an overview of experimental and observational studies assessing the relations between sleep and FV consumption from 52 human adult studies. Experimental studies are currently limited and show inconsistent results. Observational studies support a non-linear association with adults sleeping the recommended 7-9 hours/day having the highest intakes of FV. The potential mechanisms linking sleep and FV consumption are highlighted. Disrupted sleep influences FV consumption through homeostatic and non-homeostatic mechanisms. Conversely, FV consumption may influence sleep through polyphenol content via several potential pathways. Few human experimental studies have examined the effects of FV items and their polyphenols on sleep and there is a need for more studies to address this. An appreciation of the relationship between sleep and FV consumption may help optimize sleep and FV consumption and may reduce the burden of chronic diseases. This review provides implications for public health and directions for future work.
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Dietary Neurotransmitters: A Narrative Review on Current Knowledge.
Briguglio, M, Dell'Osso, B, Panzica, G, Malgaroli, A, Banfi, G, Zanaboni Dina, C, Galentino, R, Porta, M
Nutrients. 2018;10(5)
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Neurotransmitters (NTs) are chemical messengers, found mainly within the nervous system. Common NTs are acetylcholine (ACh), glutamate, γ-aminobutyric acid (GABA), dopamine, serotonin (5-HT), and histamine. Many foods are natural sources of NTs that may influence the nervous system, and therefore mood and mental health. This review paper looked at books and studies and discusses the NT content of foods and the possible implications for human health. Acetylcholine is a NT involved in muscle movement, learning and memory. Its presence is documented in more than 50 plant species, including squash, aubergine spinach and nettles. Glutamate is the most abundant excitatory NT in the brain. Glutamic acid naturally occurs in foods with high protein content. Seaweeds, cheeses, fish sauces, soy sauces, fermented beans, and tomato showed high levels of free glutamic acid. Dried cod, salami, caviar, and instant coffee powder are other sources of this amino acid. Salts of glutamic acid, such as monosodium glutamate, are added to certain foods as flavour enhancers. GABA is a calming NT. Studies have found the highest contents of GABA in raw spinach, potato, sweet potato and cruciferous vegetables such as kale and broccoli. Shiitake mushrooms and chestnuts also contained a significant amount of GABA. Dopamine plays an essential role in the coordination of body movements, motivation, and reward. Information on the content of dopamine foods is very limited. Bananas, plantains and avocado were reported to contain high levels of dopamine. 5-HT pathways modulate behaviours, eating, and sleep, and in the gut are involved in the regulation of gastrointestinal motility. In recent years, the number of studies on the content of 5-HT in plants has increased. 5-HT appeared to be prevalent in the green bananas, with higher concentrations found in the peel compared with the flesh. 5-HT was also found in peppers, paprika, hazelnut, tomatoes, pineapple, plum, passion fruit, papaya and kiwi fruit. Histamine is involved in arousal, attention, and reactivity, as well as in local immune responses. The presence of histamine in processed foods, such as aged cheeses, contributes to characteristic flavours and textures. Wine and beer may contain a significant amount of histamine. Fermented foods contain histamine. The food industry generally aims to maintain the levels of amines in foods as low as possible; consumption of fish, cured meat products, sauerkraut, and cheese varieties such as Cheddar, Swiss, Gruyère, and Gouda have been associated with amine poisoning. The significance of dietary NTs intake needs to be further investigated, as there is little data about their bioavailability or clinical implications. New studies should consider if dietary NTs can be transported across the blood-brain barriers or act on the central nervous system via other organs. The authors suggest that in future, including or excluding particular foods containing NTs could be beneficial for patients suffering from Alzheimer’s disease or dementia (an ACh diet), epilepsy or migraines (a glutamate-free diet), anxiety or insomnia (a GABA diet), Parkinson’s disease (a dopamine diet), depressive disorders (a serotonin diet), and vascular headaches (a histamine-free diet).
Abstract
Foods are natural sources of substances that may exert crucial effects on the nervous system in humans. Some of these substances are the neurotransmitters (NTs) acetylcholine (ACh), the modified amino acids glutamate and γ-aminobutyric acid (GABA), and the biogenic amines dopamine, serotonin (5-HT), and histamine. In neuropsychiatry, progressive integration of dietary approaches in clinical routine made it necessary to discern the more about some of these dietary NTs. Relevant books and literature from PubMed and Scopus databases were searched for data on food sources of Ach, glutamate, GABA, dopamine, 5-HT, and histamine. Different animal foods, fruits, edible plants, roots, and botanicals were reported to contain NTs. These substances can either be naturally present, as part of essential metabolic processes and ecological interactions, or derive from controlled/uncontrolled food technology processes. Ripening time, methods of preservation and cooking, and microbial activity further contributes to NTs. Moreover, gut microbiota are considerable sources of NTs. However, the significance of dietary NTs intake needs to be further investigated as there are no significant data on their bioavailability, neuronal/non neuronal effects, or clinical implications. Evidence-based interventions studies should be encouraged.
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Gut microbiota varies by opioid use, circulating leptin and oxytocin in African American men with diabetes and high burden of chronic disease.
Barengolts, E, Green, SJ, Eisenberg, Y, Akbar, A, Reddivari, B, Layden, BT, Dugas, L, Chlipala, G
PloS one. 2018;13(3):e0194171
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Obesity and type 2 diabetes (T2D) can lead to alterations of the composition of the gut microbiota. The gut microbiota, in turn, has been suggested to play a role in the development of psychological conditions, such as anxiety, depression and drug addiction. This cross-sectional study included 99 mostly overweight/obese African American men, with or without T2D, and with or without opioid addiction and other psychiatric disorders. The aim of the study was to determine, whether the gut microbiota composition was linked to T2D and the use of opioids in these patients. Furthermore, the researchers looked at the associations between leptin and oxytocin levels in the blood and the gut microbiota, and whether these hormone biomarkers could be indicative of obesity and psychosocial behaviour, such as opioid addiction. The authors found that some bacterial species in the gut were affected by T2D, diabetes medication and opioid use in the studied subjects. A relationship was also observed between leptin and oxytocin levels and the abundance of certain bacteria in the gut in subjects without T2D. The authors conclude that targeting the gut microbiota could be used for the management of T2D and associated psychiatric disorders. However, more studies are needed to provide further understanding of the connections between the gut microbiota and the brain.
Abstract
OBJECTIVE The gut microbiota is known to be related to type 2 diabetes (T2D), psychiatric conditions, and opioid use. In this study, we tested the hypothesis that variability in gut microbiota in T2D is associated with psycho-metabolic health. METHODS A cross-sectional study was conducted among African American men (AAM) (n = 99) that were outpatients at a Chicago VA Medical Center. The main outcome measures included fecal microbiota ecology (by 16S rRNA gene sequencing), psychiatric disorders including opioid use, and circulating leptin and oxytocin as representative hormone biomarkers for obesity and psychological pro-social behavior. RESULTS The study subjects had prevalent overweight/obesity (78%), T2D (50%) and co-morbid psychiatric (65%) and opioid use (45%) disorders. In the analysis of microbiota, the data showed interactions of opioids, T2D and metformin with Bifidobacterium and Prevotella genera. The differential analysis of Bifidobacterium stratified by opioids, T2D and metformin, showed significant interactions among these factors indicating that the effect of one factor was changed by the other (FDR-adjusted p [q] < 0.01). In addition, the pair-wise comparison showed that participants with T2D not taking metformin had a significant 6.74 log2 fold increase in Bifidobacterium in opioid users as compared to non-users (q = 2.2 x 10-8). Since metformin was not included in this pair-wise comparison, the significant 'q' suggested association of opioid use with Bifidobacterium abundance. The differences in Bifidobacterium abundance could possibly be explained by opioids acting as organic cation transporter 1 (OCT1) inhibitors. Analysis stratified by lower and higher leptin and oxytocin (divided by the 50th percentile) in the subgroup without T2D showed lower Dialister in High-Leptin vs. Low-Leptin (p = 0.03). Contrary, the opposite was shown for oxytocin, higher Dialister in High-Oxytocin vs. Low-Oxytocin (p = 0.04). CONCLUSIONS The study demonstrated for the first time that Bifidobacterium and Prevotella abundance was affected by interactions of T2D, metformin and opioid use. Also, in subjects without T2D Dialister abundance varied according to circulating leptin and oxytocin.